硝态氮(NO-3)对水稻侧根生长及其氮吸收的影响

侧根是植物吸收利用土壤养分的重要器官,其生长发育受内部遗传因子和外部环境矿质养分的影响.通过琼脂分层培养发现:局部供应NO-3可以诱导水稻( Oryza sativa L.)主根或不定根上侧根的生长.为研究旱种条件下NO-3对水稻侧根发育及其N吸收的影响,设置了3个蛭石培养实验:分根处理、全株缺N、全株供N处理.分根处理(一半根系供应3 mmol/L KNO3,另一半根系供应3 mmol/L KCl)结果表明:局部供应NO-3 能够促进水稻侧根生长.而在全株处理下,N饥饿诱导了侧根的伸长.水稻根系对NO-3的这两种反应都存在着显著的基因型差异.同时对地上部N浓度、可溶性总糖含量及N含量分析表明,这些生理指标在分根处理与全株加N处理中的差异均不显著,表明分根处理也能基本满足植株正常生长对N的需求.在分根处理中,水稻的N含量与分根处理中供N一侧的平均侧根长度存在显著正相关,这表明在养分不均一的介质中,侧根长度对水稻N素吸收具有十分重要的作用.而在N素充足的条件下,两者之间的相关性并不显著,这暗示在养分充足的环境下,侧根长度可能并不是决定根系吸收N素的主要因素.     

硝态氮（NO3^—）对水稻侧根生长及其氮吸收的影响

侧根是植物吸收利用土壤养分的重要器官 ,其生长发育受内部遗传因子和外部环境矿质养分的影响。通过琼脂分层培养发现 :局部供应NO-3 可以诱导水稻 (OryzasativaL .)主根或不定根上侧根的生长。为研究旱种条件下NO-3 对水稻侧根发育及其N吸收的影响 ,设置了 3个蛭石培养实验 :分根处理、全株缺N、全株供N处理。分根处理 (一半根系供应 3mmol/LKNO3,另一半根系供应 3mmol/LKCl)结果表明 :局部供应NO-3 能够促进水稻侧根生长。而在全株处理下 ,N饥饿诱导了侧根的伸长。水稻根系对NO-3 的这两种反应都存在着显著的基因型差异。同时对地上部N浓度、可溶性总糖含量及N含量分析表明 ,这些生理指标在分根处理与全株加N处理中的差异均不显著 ,表明分根处理也能基本满足植株正常生长对N的需求。在分根处理中 ,水稻的N含量与分根处理中供N一侧的平均侧根长度存在显著正相关 ,这表明在养分不均一的介质中 ,侧根长度对水稻N素吸收具有十分重要的作用。而在N素充足的条件下 ,两者之间的相关性并不显著 ,这暗示在养分充足的环境下 ,侧根长度可能并不是决定根系吸收N素的主要因素     

鄱阳湖南矶湿地22种植物根系碳氮及其化学计量研究

探讨湿地植物根系碳(C)、氮(N)浓度及其化学计量关系对于进一步阐明湿地生态系统细根周转及养分循环具有重要意义。基于Pregitzer的根序分级法分析了鄱阳湖南矶湿地22种植物根系全C和全N浓度。结果表明:根系全C、全N浓度及C/N值变化范围分别为:267.15—423.22 mg/g、2.22—31.05 mg/g和2.27—71.78。1—2级根全C、全N及C/N之间具有显著相关性,但与3级根不相关。根系全C和C/N随根序的升高而增加,全N则随根序升高而降低,根系分级在湿地植物C、N化学计量关系研究中十分必要。根序、物种及其交互作用均显著影响研究区植物根系的全C、全N浓度及C/N计量关系。根系C/N化学计量关系在不同生境间未发生显著变化,表明群落尺度下的C/N稳定性高于个体水平。     

植物残体对青藏高原高寒草甸土壤、微生物和胞外酶C∶N∶P化学计量特征的影响

植物残体是引起土壤、微生物和胞外酶C∶N∶P改变的关键因素,但是其作用机理尚不明确。本研究以青藏高原东缘高寒草甸为对象,通过测定土壤、微生物生物量和胞外酶活性等指标,探究移除地上植物或根系及植物残体添加对土壤、微生物和胞外酶C∶N∶P的影响。结果表明: 与无人为扰动草甸相比,移除地上植物显著降低了土壤C∶N(变幅为-23.7%,下同)、C∶P(-14.7%)、微生物生物生物量C∶P、N∶P,显著提高了微生物生物量C∶N、胞外酶C∶N∶P。与移除地上植物相比,移除地上植物和根系显著降低了土壤C∶N(-11.6%)、C∶P(-24.0%)、N∶P(-23.3%)和微生物生物量C∶N,显著提高了微生物生物量N∶P和胞外酶N∶P;移除地上植物后添加植物残体显著提高了微生物生物量C∶N、C∶P和胞外酶C∶N,显著降低了胞外酶N∶P。与移除地上植物和根系相比,移除地上植物和根系后添加植物残体显著降低了土壤C∶N(-16.4%)、微生物生物量C∶P、N∶P和胞外酶N∶P,显著提高了胞外酶C∶N。综上可知,去除植物显著影响土壤、微生物和胞外酶的C∶N∶P,微生物生物量和胞外酶C∶N∶P对植物残体的响应更为敏感。有无根系是添加植物残体时土壤、微生物和胞外酶的生态化学计量稳定性强弱的关键所在。添加植物残体的措施适用于植物根系尚且完好的草甸,有利于高寒草甸土壤碳固存,对没有根系的草甸土壤可能不适用,会增加土壤CO₂排放。     

大兴安岭典型森林沼泽植物叶片和细根碳氮磷化学计量特征

探究大兴安岭典型森林沼泽不同植物叶片和细根生态化学计量特征,能够为进一步认识高纬度气候敏感生态系统养分利用策略和物质循环过程提供依据。对大兴安岭地区兴安落叶松-苔草、兴安落叶松-笃斯越桔-藓类和兴安落叶松-杜香-泥炭藓3种典型森林沼泽19种优势和亚优势维管植物叶片和细根碳氮磷计量特征(C∶N∶P)进行比较,分析不同森林沼泽类型、植物生长型和菌根类型叶片和细根C∶N∶P差异,通过标准化主轴回归分析叶片与细根C∶N∶P的关系。结果表明: 叶片C∶N∶P在种间水平具有最大的变异(42.5%～84.6%),且叶片和细根种间变异大小均为N∶P>C∶N>C∶P。土壤养分和水分含量较高的兴安落叶松-苔草沼泽叶片与细根C∶N和C∶P值较低,且3种森林沼泽植物叶片和细根N∶P均小于10,受N限制。草本植物叶片C∶P和细根C∶N、C∶P显著低于木本植物。外生菌根和杜鹃花类菌根植物叶片和细根C∶N和C∶P高于丛枝菌根和无菌根植物,且杜鹃花类菌根植物叶片和细根C∶P显著高于外生菌根植物。不同森林沼泽、生长型、菌根类型植物叶片和细根C∶N和C∶P差异明显,而N∶P相对稳定。森林沼泽植物叶片与细根C∶N、C∶P和N∶P呈线性正相关,植物地上与地下部分在生态化学计量特征上存在协同。     

长白山白桦山杨次生林细根形态特征和解剖结构对氮沉降的响应

根系作为植物与土壤物质交换和养分循环的桥梁,长期以来一直是生态学研究的热点。于2017年7月植物生长季,对长白山模拟11年氮(N)沉降控制试验样地的白桦(Betula platyphylla)山杨(Populus davidiana)天然次生林进行了根系采样,并利用根序法研究了根系形态特征和解剖结构对不同梯度N添加处理的响应,旨在探求两物种根系之间潜在生态联系。本试验共设置了三个N添加梯度,分别为对照(CK,0 g N m~(-2 )a~(-1))、低N处理(T_L,2.5 g N m~(-2 )a~(-1))和高N处理(T_H,5.0 g N m~(-2 )a~(-1))。研究结果如下:1)T_L显著抑制白桦和山杨前三级细根皮层厚度的生长。白桦通过增加皮层细胞直径(一级根增加了72.77%,二级根增加了53.22%,三级根增加了39.96%)但减少皮层层数来降低皮层厚度,而山杨主要通过皮层细胞直径的减少(一级根下降了40.80%,二级根下降了28.17%)来降低其皮层厚度。2)T_H显著抑制山杨前三级细根生长。主要通过增加皮层厚度(一级根增加了68.78%,二级根增加了50.81%,三级根增加了88.53%)以及降低导管横截面积来抑制吸收养分,从而达到影响生长的目的。3)白桦T_H相比于T_L细根直径呈抑制生长状态。其主要通过抑制中柱直径(一级根下降了17.61%,二级根下降了16.89%,三级根下降了20.62%)的生长来实现。以上结果表明,在同一立地条件下,白桦和山杨的细根对不同浓度N沉降的响应方式不同。     

模拟氮沉降对杉木幼苗细根化学计量学特征的影响

为了揭示全球氮(N)沉降对杉木人工林细根碳(C)、N、磷(P)元素组成的影响,在福建三明陈大国有林场开展杉木(Cunninghamia lanceolata)幼苗模拟N沉降试验,设置了对照(CK)、低N(LN,40 kg N hm~(-2)a~(-1))、高N(HN,80 kg N hm~(-2)a~(-1))3个处理,每个处理5个重复。采用内生长环法通过2年4次取样探讨N沉降对细根C、N、P化学计量学的影响。结果显示:(1) N添加在2015年降低细根C浓度,此后低N处理无影响,高N添加在2016年增加了细根C浓度;高N添加提高了细根(特别是0—1 mm细根) N浓度,但低N添加则无显著影响,甚至在2016年7月显著降低细根N浓度; N添加在2015年对细根P浓度无显著影响,但在2016年导致细根(特别是0—1 mm细根) P浓度降低。(2)低N添加在2016年显著提高细根的C∶N比,而高N添加则在2015年1月显著降低细根的C∶N比;低N添加对细根N∶P比没有显著影响,而高N添加则在大部分取样时间里显著增加了细根N∶P比。(3)不同处理细根C浓度、C∶N比均随着时间的增加呈增加趋势,而细根N浓度和N∶P比呈降低趋势。本研究表明,N添加对杉木细根化学计量学特征的影响因不同N添加水平而异,并受苗木生长的稀释效应所调节。     

土壤紧实胁迫对黄瓜根系生长及氮代谢的影响

用容重分别为1.25 g·cm-3(疏松土壤,对照)和1.55 g·cm-3(紧实土壤)的土壤进行盆栽试验,研究了土壤紧实胁迫对‘津春4号’黄瓜不同生育期根系生长、呼吸速率、活力及氮代谢的影响.结果表明:在土壤紧实胁迫条件下,黄瓜不同生育期根系总长度、表面积、分根数和根尖数均显著下降,根系的伸长生长及侧根的发生受到显著抑制,而根系的加粗生长得到激发,平均直径显著增加;根系活力和根系呼吸速率显著下降;根系中的NO3-、游离氨基酸和可溶性蛋白含量大幅下降,硝酸还原酶、谷氨酰胺合成酶和谷氨酸合酶活性显著降低,NH4+含量显著增加.说明在土壤紧实胁迫条件下黄瓜根系对硝态氮的吸收量减少,氨同化作用受到抑制,氮代谢显著受阻.     

伊犁河谷苦豆子C、N、P含量变化及化学计量特征

研究苦豆子不同器官中碳、氮、磷元素的化学计量特征的季节变化有助于深入了解该植物蔓延的生态学机制。系统分析了伊犁河谷苦豆子根、茎、叶的碳(C)、氮(N)、磷(P)化学计量特征及其季节动态变化。结果表明∶苦豆子C、N、P含量均值分别为391.40、13.17、1.51mg/g,C∶N、N∶P、C∶P均值分别为45.61、8.52、326.38。苦豆子根、茎、叶在整个生长季内C、N、P均值含量变化一致,为叶茎根。在生态化学计量特征的分析中规律则不同,C含量随着生长时期的增加而增加,N和P的含量则随着生长时期的增加而减少;苦豆子根系中的C、N、P含量有随着深度变化而递减的趋势;器官间的差异性说明植物在不同生长时期,各器官对C、N、P的吸收利用具有特异性。植物叶片中C、N、P含量和N∶P普遍较低,苦豆子生长受N、P的共同限制,更容易受到N元素的限制。     

N添加对西南亚高山红桦林根系分泌物及其介导的养分转化过程的影响

目前缺乏对根系分泌物通量以及相关生态后果对不同氮(N)沉降水平响应方向和幅度的深入理解,该研究以西南亚高山典型的红桦(Betula albosinensis)林为研究对象,通过野外原位N添加试验模拟不同氮沉降水平(对照组,0 kg·hm^-2·a(-1);低氮处理,25 kg·hm^-2·a(-1);高氮处理,50 kg·hm^-2·a(-1)),分析了红桦林根系分泌物C输入通量及其介导的根际土壤养分循环过程对不同N添加水平的差异化响应,试图揭示不同N添加处理对红桦根系分泌物C输入通量及其介导的土壤养分转化过程的影响。结果表明：(1)N添加显著抑制了红桦林根系分泌物C输入速率(其中低氮(N25)条件下单位根生物量根系分泌速率均值降低约14.87%)和年C输入通量(低氮条件下降低了约45.01%)(P<0.05),其高氮处理的抑制效应更强。(2)N添加显著抑制了红桦林N矿化速率及其相关的微生物胞外酶活性(P<0.05),并显著降低了其根际效应;N沉降显著抑制了根系分泌物C输入通量及其介导的土壤养分转化过程,并且这种抑...     

Signalling mechanisms underlying the morphological responses of the root system to nitrogen in Arabidopsis thaliana

Plants display considerable developmental plasticity in response to changing environmental conditions. The adaptations of the root system to variations in N supply are an excellent example of such developmental plasticity. In Arabidopsis, four morphological adaptations to the N supply have been characterized: (i) a localized stimulatory effect of external nitrate on lateral root elongation; (ii) a systemic inhibitory effect of high tissue nitrate concentrations on the activation of lateral root meristems; (iii) a suppression of lateral root initiation by high C:N ratios, and (iv) an inhibition of primary root growth and stimulation of root branching by external L-glutamate. These responses have provided valuable experimental systems for the study of N signalling in plants. This article will highlight some recent progress made in this direction from studies using the Arabidopsis root system. One recent development of note has been the emerging evidence of a regulatory role of nitrate transporters in some of the responses. It has been reported that the AtNRT1.1 (CHL1) dual-affinity nitrate transporter acts upstream of the ANR1 MADS box gene in mediating the stimulatory effect of a localized nitrate supply on lateral root proliferation. The AtNRT2.1 high-affinity nitrate transporter seems to be involved in the repression of lateral root initiation by high C:N ratios. The systemic inhibitory effect of high nitrate supply on lateral root development, which is mediated by abscisic acid (ABA), may be linked to the recently identified ABA receptor, FCA. The newly discovered root architectural response to external L-glutamate potentially offers a valuable experimental tool for studying the biological function of plant glutamate receptors and amino acid signalling.     

Regulation of Arabidopsis root development by nitrate availability

When the root systems of many plant species are exposed to a localized source of nitrate (NO3- they respond by proliferating their lateral roots to colonize the nutrient-rich zone. This study reviews recent work with Arabidopsis thaliana in which molecular genetic approaches are being used to try to understand the physiological and genetic basis for this response. These studies have led to the conclusion that there are two distinct pathways by which NO3- modulates root branching in Arabidopsis. On the one hand, meristematic activity in lateral root tips is stimulated by direct contact with an enriched source of NO3- (the localized stimulatory effect). On the other, a critical stage in the development of the lateral root (just after its emergence from the primary root) is highly susceptible to inhibition by a systemic signal that is related to the amount of NO3- absorbed by the plant (the systemic inhibitory effect). Evidence has been obtained that the localized stimulatory effect is a direct effect of the NO3- ion itself rather than a nutritional effect. A NO3(-)-inducible MADS-box gene (ANR1) has been identified which encodes a component of the signal transduction pathway linking the external NO3- supply to the increased rate of lateral root elongation. Experiments using auxin-resistant mutants have provided evidence for an overlap between the auxin and NO3- response pathways in the control of lateral root elongation. The systemic inhibitory effect, which does not affect lateral root initiation but delays the activation of the lateral root meristem, appears to be positively correlated with the N status of the plant and is postulated to involve a phloem-mediated signal from the shoot.     

Natural variation of the root morphological response to nitrate supply in Arabidopsis thaliana

Nitrogen fertilization increases crop yield but excessive nitrate use can be a major environmental problem due to soil leaching or greenhouse gas emission. Root traits have been seldom considered as selection criteria to improve Nitrogen Use Efficiency of crops, due to the difficulty of measuring root traits under field conditions. Nonetheless, learning about mechanisms of lateral root (LR) growth stimulation or repression by nitrate availability could help to redesign root system architecture (RSA), a strategy aimed at developing plants with a dense and profound root system and with higher N uptake efficiency. Here, we explored the genetic diversity provided by natural populations of the model species Arabidopsis thaliana to identify potentially adaptive differences in biomass production and root morphology in response to nitrate availability. A core collection of 24 accessions that maximizes the genetic diversity within the species and Col-0 (the reference accession) were grown vertically on agar medium at moderate (N+) nitrate level for 6 days and then transferred to the same condition or to low (N?) nitrate concentration for 7 days. There was a major nutritional effect on the shoot biomass and root to shoot biomass ratio. The variation of the root biomass and RSA traits (primary root length, LRs number, LR mean length, total LRs length and LR densities) was primarily genetically determined. Differences in RSA traits between accessions were somewhat more pronounced at N?. Some accessions produced almost no visible LRs (Pyl-1, N13) at N?, while other produced up to a dozen (Kn-0). Taken together our data illustrate that natural variation exists within Arabidopsis for the studied traits. The identification of RSA ideotypes in the N response will facilitate further analysis of quantitative traits for root morphology.     

Disentangling the rhizosphere effect on nitrate reducers and denitrifiers: insight into the role of root exudates

To determine to which extent root-derived carbon contributes to the effects of plants on nitrate reducers and denitrifiers, four solutions containing different proportions of sugar, organic acids and amino acids mimicking maize root exudates were added daily to soil microcosms at a concentration of 150 microg C g(-1) of soil. Water-amended soils were used as controls. After 1 month, the size and structure of the nitrate reducer and denitrifier communities were analysed using the narG and napA, and the nirK, nirS and nosZ genes as molecular markers respectively. Addition of artificial root exudates (ARE) did not strongly affect the structure or the density of nitrate reducer and denitrifier communities whereas potential nitrate reductase and denitrification activities were stimulated by the addition of root exudates. An effect of ARE composition was also observed on N(2)O production with an N(2)O:(N(2)O + N(2)) ratio of 0.3 in microcosms amended with ARE containing 80% of sugar and of 1 in microcosms amended with ARE containing 40% of sugar. Our study indicated that ARE stimulated nitrate reduction or denitrification activity with increases in the range of those observed with the whole plant. Furthermore, we demonstrated that the composition of the ARE affected the nature of the end-product of denitrification and could thus have a putative impact on greenhouse gas emissions.     

结合态氮对根瘤菌生长液诱导的苜蓿根毛变形的抑制

以苜蓿根瘤菌和其宿主苜蓿为材料,由结合态氮影响苜蓿根瘤菌生长液诱导宿主根毛变形的功能发现,硝态氮和铵态氮均能有效地抑制根瘤菌生长液诱导的宿主根毛变形。而其抑制作用随结合态氮浓度的增加、作用时间的延长而增强。该抑制作用发生在结合态氮浓度和作用时间分别达到1mmol/L和12h时,或当其浓度和作用时间分别为6mmol/L和48h时,根瘤菌生长液引起根毛变形的植株百分率下降到10％。硝态氮与铵态氮抑制根瘤菌生长液诱导根毛变形的作用相类似。     

Mapping QTLs for root traits under different nitrate levels at the seedling stage in maize (Zea mays L.)

Nitrogen (N) loss is a worldwide problem in crop production. Apart from reasonable N fertilizer application, breeding N efficient cultivars provides an alternative way. Root architecture is an important factor determining N acquisition. However, little is known about the molecular genetic basis for root growth in relation to N supply. In the present study, an F₈ maize (Zea may L.) recombinant inbred (RI) population consisting of 94 lines was used to identify the QTLs for root traits under different nitrate levels. The lateral root length (LRL), axial root length (ARL), maximal axial root length (MARL), axial root number (ARN) and average axial root length (AARL) were evaluated under low N (LN) and high N (HN) conditions in a hydroponics system. A total of 17 QTLs were detected among which 14 loci are located on the same chromosome region as published QTLs for root traits. A major QTL on chromosome 1 (between bnlg1025 and umc2029) for the AARL under LN could explain 43.7% of the phenotypic variation. This QTL co-localizes with previously reported QTLs that associate with root traits, grain yield, and N uptake. Our results indicate that longer axial roots are important for efficient N acquisition and the major QTL for AARL may be used as a marker in breeding N efficient maize genotypes.     

The effect of marine bioactive substances (N PRO) and exogenous cytokinins on nitrate reductase activity in Arabidopsis thaliana

We investigated the effect of exogenous cytokinins and marine bioactive substances containing seaweed extracts (marketed by the ROULLIER Group under the trade name N PRO^TM.) on nitrate reductase activity in Arabidopsis . Cytokinins, applied either directly in the growth medium or as a foliar spray, did not significantly influence nitrate reductase activity in extracts from in vitro grown Arabidopsis plants. Conversely, Arabidopsis grown in the presence of or sprayed with N PRO had increased nitrate reductase activity. This stimulatory effect of N PRO was even higher when the plants were grown on low nitrate concentration, suggesting that these marine bioactive substances may be beneficial for plant growth in adverse nutritional conditions.     

The partitioning of nitrate assimilation between root and shoot of higher plants

Abstract The partitioning of nitrate assimilation between root and shoot of higher plant species is indicated by the relative proportions of total plant nitrate reductase activity (NRA) in the two plant parts and the relative concentrations of nitrate and reduced N in the xylem sap. These have been collated here from the literature and temperate and tropical species compared. Both the distribution of NRA and xylem sap nitrate: reduced N indicate that the following four generalizations can be made.

• 1 Temperate, perennial species growing in low external nitrate concentrations (about 1 mol m^?3) carry out most of their nitrate assimilation in the root. As external nitrate concentration increases (in the range found in agricultural soils, 1–20 mol m^?3), shoot nitrate assimilation becomes increasingly important.
• 2 Temperate, annual legume species growing in low external nitrate concentrations carry out most of their nitrate assimilation in the root. Shoot nitrate assimilation increases in importance as external nitrate concentration is increased.
• 3 Temperate, annual non-legume species vary greatly in their partitioning of nitrate assimilation between root and shoot when growing in low external nitrate concentrations. Regardless of the proportion carried out in the root at low external nitrate concentrations, nitrate assimilation in the shoot becomes increasingly important as external nitrate concentration is increased.
• 4 Tropical and subtropical species, annual and perennial, carry out a substantial proportion of their nitrate assimilation in the shoot when growing in low external nitrate concentrations. The partitioning of nitrate assimilation between root and shoot remains constant as external nitrate concentration increases.

It is proposed that a greater proportion of nitrate assimilation occurs in the shoot when an increase in the rate of nitrate uptake does not induce an increase in NR level in the root. Thus, a greater proportion of the nitrate taken up remains unassimilated and is passed into the xylem. A constant partitioning of nitrate assimilation between root and shoot is achieved by balancing NR levels in the root with rates of nitrate uptake. The advantages and disadvantages of assimilating nitrate in either the root or shoot are discussed in relation to temperate and tropical habitats.     

Physiological responses of <Emphasis Type="Italic">Catharanthus roseus</Emphasis> to different nitrogen forms

The responses of carbon and nitrogen metabolisms in the medical plant Catharanthus roseus to the nitrogen solutions (N1, N2 and N3) containing different ratio of nitrate to ammonium (1:0, N1; 1:1, N2; 1:3, N3) were investigated here. The plants in N3 nitrogen solution were strongly inhibited in photosynthetic gas exchange and carbohydrate accumulation, reflecting the toxicity symptom of excess ammonium continuously accumulated in plants. The treatment with N2 nitrogen solution, however, displayed an obviously synergistic effect on plant growth and metabolisms in contrast to nitrate as the sole source. The short-term (7 days) exposure of plants to N2 nitrogen solution resulted in an increased shoot/root ratio, leaf mass ratio, and Pn, as well as the elevated levels of sucrose, glutamate, aspartate, proline and threonine. The plants in N2 nitrogen solution accumulated twofold catharanthine and vinblastine than did the plants in N1 or N3 nitrogen solution after the long-term incubation. Internal nitrate had an increased accumulation in the plants in N2 nitrogen solution compared to the counterparts. The supply of N2 or N3 nitrogen solution to plants for 7 days induced an over tenfold increase of ammonium in leaves as compared to the case using N1 nitrogen solution. The increased ammonium ion promoted the activities of NADH-dependent glutamate dehydrogenase (NADH-GDH) both in the leaf and root of plants. Under the ammonium-containing solution (N2 and N3 nitrogen solutions), there was a significantly increased activity for glutamine synthase (GS) in the root during experiment and for nitrate reductase (NR) in the leaf and root only after 21 days of treatment. The performed correlation analysis revealed a negative relation between soluble sugars and internal ammonium, whereas a positive correlation of alkaloid production with glutamate and aspartate.